A litho-litho-etch double patterning method including forming a resist layer by coating a substrate with a resist composition; exposing the resist layer to a first radiant energy density of UV rays; forming a first pattern in the resist layer by developing the resist layer with a positive developer;
A litho-litho-etch double patterning method including forming a resist layer by coating a substrate with a resist composition; exposing the resist layer to a first radiant energy density of UV rays; forming a first pattern in the resist layer by developing the resist layer with a positive developer; exposing the resist layer to a second radiant energy density of UV rays; and forming a second pattern in the resist layer by developing the resist layer with a negative developer, the second pattern including one or more features of the first pattern.
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1. A double patterning method comprising: forming a sole resist layer by coating a substrate with a resist composition wherein solubility of the resist composition in a positive developer increases upon irradiation with ultraviolet (UV) rays of a first radiant energy density and solubility of the re
1. A double patterning method comprising: forming a sole resist layer by coating a substrate with a resist composition wherein solubility of the resist composition in a positive developer increases upon irradiation with ultraviolet (UV) rays of a first radiant energy density and solubility of the resist composition in a negative developer decreases upon irradiation with UV rays of a second radiant energy density, the second radiant energy density of UV rays being greater than the first radiant energy density of UV rays;exposing the resist layer to the first radiant energy density of UV rays through at least one first opening in a first hardmask;forming a first pattern in the resist layer by developing the resist layer with the positive developer, the at least one first opening in the first hardmask creating the first pattern;exposing the resist layer to the second radiant energy density of UV rays through at least one second opening in a second hardmask, the at least one second opening encompassing and being larger than the at least one first opening in the first hardmask, the at least one second opening in the second hardmask exposing at least one portion of the resist layer not exposed to the first radiant energy density of UV rays by the at least one first opening in the first hardmask; andforming a second pattern in the resist layer by developing the resist layer with the negative developer, the at least one portion of the resist layer exposed to the second radiant energy density of UV rays creating the second pattern, the second pattern including one or more features of the first pattern. 2. The method of claim 1, further comprising at least one of: heating the resist layer after the exposing of the resist layer to the first radiant energy density of UV rays but before the developing of the resist layer with the positive developer; andheating the resist layer after the exposing of the resist layer to the second radiant energy density of UV rays but before the developing of the resist layer with the negative developer. 3. The method of claim 1, wherein the first hardmask is modified such that the at least one first opening in the first hardmask is widened to create the second hardmask containing the at least one second opening. 4. The method of claim 1, wherein the first radiant energy density of UV rays and the second radiant energy density of UV rays are within a range of from approximately 0.1 to approximately 100 millijoules per square centimeter (mJ/cm2), and the second radiant energy density is approximately 5 to approximately 50 mJ/cm2 greater than the first radiant energy density. 5. The method of claim 4, wherein the second radiant energy density of UV rays is approximately two times the first radiant energy density of UV rays. 6. A double patterning method comprising: forming a resist layer by coating a substrate with a resist composition wherein solubility of the resist composition in a positive developer increases upon irradiation with ultraviolet (UV) rays of a first radiant energy density and solubility of the resist composition in a negative developer decreases upon irradiation with UV rays of a second radiant energy density, the second radiant energy density of UV rays being greater than the first radiant energy density of UV rays;exposing the resist layer to the first radiant energy density of UV rays through at least one first opening in a first hardmask;forming a first pattern in the resist layer by developing the resist layer with the positive developer, the at least one first opening in the first hardmask creating the first pattern;exposing the resist layer to the second radiant energy density of UV rays through at least one second opening in a second hardmask, the at least one second opening encompassing and being larger than the at least one first opening in the first hardmask, the at least one second opening in the second hardmask exposing at least one portion of the resist layer not exposed to the first radiant energy density of UV rays by the at least one first opening in the first hardmask; andforming a second pattern in the resist layer by developing the resist layer with the negative developer, the at least one portion of the resist layer exposed to the second radiant energy density of UV rays creating the second pattern, the second pattern including one or more features of the first pattern;wherein the exposing of the resist layer to the first radiant energy density of UV rays generates an acid in an area substantially equal to an area of the resist layer exposed to the first radiant energy density of UV rays, wherein a concentration of the acid remaining in the resist layer after the developing of the resist layer with the negative developer is substantially uniform throughout the resist layer. 7. The method of claim 6, further comprising at least one of: heating the resist layer after the exposing of the resist layer to the first radiant energy density of UV rays but before the developing of the resist layer with the positive developer; andheating the resist layer after the exposing of the resist layer to the second radiant energy density of UV rays but before the developing of the resist layer with the negative developer. 8. The method of claim 6, wherein the first hardmask is modified such that the at least one first opening in the first hardmask is widened to create the second hardmask containing the at least one second opening. 9. The method of claim 6, wherein the first radiant energy density of UV rays and the second radiant energy density of UV rays are within a range of from approximately 0.1 to approximately 100 millijoules per square centimeter (mJ/cm2), and the second radiant energy density is approximately 5 to approximately 50 mJ/cm2 greater than the first radiant energy density. 10. The method of claim 9, wherein the second radiant energy density of UV rays is approximately two times the first radiant energy density of UV rays. 11. A double patterning method comprising: forming a resist layer by coating a substrate with a resist composition;exposing the resist layer to a first radiant energy density of ultraviolet (UV) rays through at least one first opening in a first hardmask;forming a first pattern in the resist layer by developing the resist layer with a positive developer, the at least one first opening in the first hardmask creating the first pattern;exposing the resist layer to a second radiant energy density of UV rays through at least one second opening in a second hardmask, the at least one second opening encompassing and being larger than the at least one first opening in the first hardmask, the at least one second opening in the second hardmask exposing at least one portion of the resist layer not exposed to the first radiant energy density of UV rays by the at least one first opening in the first hardmask; andforming a second pattern in the resist layer by developing the resist layer with a negative developer, the at least one portion of the resist layer exposed to the second radiant energy density of UV rays creating the second pattern, the second pattern including one or more features of the first pattern;wherein the forming of the first and second patterns in the resist layer creates at least two resist coating features. 12. The method of claim 11, wherein solubility of the resist composition in the positive developer increases upon irradiation with the first radiant energy density of UV rays and solubility of the resist composition in the negative developer decreases upon irradiation with the second radiant energy density of UV rays, the second radiant energy density of UV rays being greater than the first radiant energy density of UV rays. 13. The method of claim 11, wherein the at least two resist coating features are multidirectional. 14. The method of claim 13, wherein at least two of the at least two resist coating features are orthogonal to one another. 15. The method of claim 11, further comprising at least one of: heating the resist layer after the exposing of the resist layer to the first radiant energy density of UV rays but before the developing of the resist layer with the positive developer; andheating the resist layer after the exposing of the resist layer to the second radiant energy density of UV rays but before the developing of the resist layer with the negative developer. 16. The method of claim 11, wherein the first hardmask is modified such that the at least one first opening in the first hardmask is widened to create the second hardmask containing the at least one second opening. 17. The method of claim 11, wherein the first radiant energy density of UV rays and the second radiant energy density of UV rays are within a range of from approximately 0.1 to approximately 100 millijoules per square centimeter (mJ/cm2), and the second radiant energy density is approximately 5 to approximately 50 mJ/cm2 greater than the first radiant energy density.
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